/* * Copyright (C) 2012 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include <gtest/gtest.h> #include <errno.h> #include <fcntl.h> #include <limits.h> #include <math.h> #include <stdio.h> #include <sys/types.h> #include <sys/socket.h> #include <sys/stat.h> #include <unistd.h> #include <wchar.h> #include <locale.h> #include <string> #include <thread> #include <vector> #include <android-base/file.h> #include "BionicDeathTest.h" #include "utils.h" #if defined(NOFORTIFY) #define STDIO_TEST stdio_nofortify #define STDIO_DEATHTEST stdio_nofortify_DeathTest #else #define STDIO_TEST stdio #define STDIO_DEATHTEST stdio_DeathTest #endif using namespace std::string_literals; class stdio_DeathTest : public BionicDeathTest {}; class stdio_nofortify_DeathTest : public BionicDeathTest {}; static void SetFileTo(const char* path, const char* content) { FILE* fp; ASSERT_NE(nullptr, fp = fopen(path, "w")); ASSERT_NE(EOF, fputs(content, fp)); ASSERT_EQ(0, fclose(fp)); } static void AssertFileIs(const char* path, const char* expected) { FILE* fp; ASSERT_NE(nullptr, fp = fopen(path, "r")); char* line = nullptr; size_t length; ASSERT_NE(EOF, getline(&line, &length, fp)); ASSERT_EQ(0, fclose(fp)); ASSERT_STREQ(expected, line); free(line); } static void AssertFileIs(FILE* fp, const char* expected, bool is_fmemopen = false) { rewind(fp); char line[1024]; memset(line, 0xff, sizeof(line)); ASSERT_EQ(line, fgets(line, sizeof(line), fp)); ASSERT_STREQ(expected, line); if (is_fmemopen) { // fmemopen appends a trailing NUL byte, which probably shouldn't show up as an // extra empty line, but does on every C library I tested... ASSERT_EQ(line, fgets(line, sizeof(line), fp)); ASSERT_STREQ("", line); } // Make sure there isn't anything else in the file. ASSERT_EQ(nullptr, fgets(line, sizeof(line), fp)) << "junk at end of file: " << line; } TEST(STDIO_TEST, flockfile_18208568_stderr) { // Check that we have a _recursive_ mutex for flockfile. flockfile(stderr); feof(stderr); // We don't care about the result, but this needs to take the lock. funlockfile(stderr); } TEST(STDIO_TEST, flockfile_18208568_regular) { // We never had a bug for streams other than stdin/stdout/stderr, but test anyway. FILE* fp = fopen("/dev/null", "w"); ASSERT_TRUE(fp != nullptr); flockfile(fp); feof(fp); funlockfile(fp); fclose(fp); } TEST(STDIO_TEST, tmpfile_fileno_fprintf_rewind_fgets) { FILE* fp = tmpfile(); ASSERT_TRUE(fp != nullptr); int fd = fileno(fp); ASSERT_NE(fd, -1); struct stat sb; int rc = fstat(fd, &sb); ASSERT_NE(rc, -1); ASSERT_EQ(sb.st_mode & 0777, 0600U); rc = fprintf(fp, "hello\n"); ASSERT_EQ(rc, 6); AssertFileIs(fp, "hello\n"); fclose(fp); } TEST(STDIO_TEST, tmpfile64) { FILE* fp = tmpfile64(); ASSERT_TRUE(fp != nullptr); fclose(fp); } TEST(STDIO_TEST, dprintf) { TemporaryFile tf; int rc = dprintf(tf.fd, "hello\n"); ASSERT_EQ(rc, 6); lseek(tf.fd, 0, SEEK_SET); FILE* tfile = fdopen(tf.fd, "r"); ASSERT_TRUE(tfile != nullptr); AssertFileIs(tfile, "hello\n"); fclose(tfile); } TEST(STDIO_TEST, getdelim) { FILE* fp = tmpfile(); ASSERT_TRUE(fp != nullptr); const char* line_written = "This is a test"; int rc = fprintf(fp, "%s", line_written); ASSERT_EQ(rc, static_cast<int>(strlen(line_written))); rewind(fp); char* word_read = nullptr; size_t allocated_length = 0; const char* expected[] = { "This ", " ", "is ", "a ", "test" }; for (size_t i = 0; i < 5; ++i) { ASSERT_FALSE(feof(fp)); ASSERT_EQ(getdelim(&word_read, &allocated_length, ' ', fp), static_cast<int>(strlen(expected[i]))); ASSERT_GE(allocated_length, strlen(expected[i])); ASSERT_STREQ(expected[i], word_read); } // The last read should have set the end-of-file indicator for the stream. ASSERT_TRUE(feof(fp)); clearerr(fp); // getdelim returns -1 but doesn't set errno if we're already at EOF. // It should set the end-of-file indicator for the stream, though. errno = 0; ASSERT_EQ(getdelim(&word_read, &allocated_length, ' ', fp), -1); ASSERT_EQ(0, errno); ASSERT_TRUE(feof(fp)); free(word_read); fclose(fp); } TEST(STDIO_TEST, getdelim_invalid) { FILE* fp = tmpfile(); ASSERT_TRUE(fp != nullptr); char* buffer = nullptr; size_t buffer_length = 0; // The first argument can't be NULL. errno = 0; ASSERT_EQ(getdelim(nullptr, &buffer_length, ' ', fp), -1); ASSERT_EQ(EINVAL, errno); // The second argument can't be NULL. errno = 0; ASSERT_EQ(getdelim(&buffer, nullptr, ' ', fp), -1); ASSERT_EQ(EINVAL, errno); fclose(fp); } TEST(STDIO_TEST, getdelim_directory) { FILE* fp = fopen("/proc", "r"); ASSERT_TRUE(fp != nullptr); char* word_read; size_t allocated_length; ASSERT_EQ(-1, getdelim(&word_read, &allocated_length, ' ', fp)); fclose(fp); } TEST(STDIO_TEST, getline) { FILE* fp = tmpfile(); ASSERT_TRUE(fp != nullptr); const char* line_written = "This is a test for getline\n"; const size_t line_count = 5; for (size_t i = 0; i < line_count; ++i) { int rc = fprintf(fp, "%s", line_written); ASSERT_EQ(rc, static_cast<int>(strlen(line_written))); } rewind(fp); char* line_read = nullptr; size_t allocated_length = 0; size_t read_line_count = 0; ssize_t read_char_count; while ((read_char_count = getline(&line_read, &allocated_length, fp)) != -1) { ASSERT_EQ(read_char_count, static_cast<int>(strlen(line_written))); ASSERT_GE(allocated_length, strlen(line_written)); ASSERT_STREQ(line_written, line_read); ++read_line_count; } ASSERT_EQ(read_line_count, line_count); // The last read should have set the end-of-file indicator for the stream. ASSERT_TRUE(feof(fp)); clearerr(fp); // getline returns -1 but doesn't set errno if we're already at EOF. // It should set the end-of-file indicator for the stream, though. errno = 0; ASSERT_EQ(getline(&line_read, &allocated_length, fp), -1); ASSERT_EQ(0, errno); ASSERT_TRUE(feof(fp)); free(line_read); fclose(fp); } TEST(STDIO_TEST, getline_invalid) { FILE* fp = tmpfile(); ASSERT_TRUE(fp != nullptr); char* buffer = nullptr; size_t buffer_length = 0; // The first argument can't be NULL. errno = 0; ASSERT_EQ(getline(nullptr, &buffer_length, fp), -1); ASSERT_EQ(EINVAL, errno); // The second argument can't be NULL. errno = 0; ASSERT_EQ(getline(&buffer, nullptr, fp), -1); ASSERT_EQ(EINVAL, errno); fclose(fp); } TEST(STDIO_TEST, printf_ssize_t) { // http://b/8253769 ASSERT_EQ(sizeof(ssize_t), sizeof(long int)); ASSERT_EQ(sizeof(ssize_t), sizeof(size_t)); // For our 32-bit ABI, we had a ssize_t definition that confuses GCC into saying: // error: format '%zd' expects argument of type 'signed size_t', // but argument 4 has type 'ssize_t {aka long int}' [-Werror=format] ssize_t v = 1; char buf[32]; snprintf(buf, sizeof(buf), "%zd", v); } // https://code.google.com/p/android/issues/detail?id=64886 TEST(STDIO_TEST, snprintf_a) { char buf[BUFSIZ]; EXPECT_EQ(23, snprintf(buf, sizeof(buf), "<%a>", 9990.235)); EXPECT_STREQ("<0x1.3831e147ae148p+13>", buf); } TEST(STDIO_TEST, snprintf_lc) { char buf[BUFSIZ]; wint_t wc = L'a'; EXPECT_EQ(3, snprintf(buf, sizeof(buf), "<%lc>", wc)); EXPECT_STREQ("<a>", buf); } TEST(STDIO_TEST, snprintf_C) { // Synonym for %lc. char buf[BUFSIZ]; wchar_t wc = L'a'; EXPECT_EQ(3, snprintf(buf, sizeof(buf), "<%C>", wc)); EXPECT_STREQ("<a>", buf); } TEST(STDIO_TEST, snprintf_ls) { char buf[BUFSIZ]; wchar_t* ws = nullptr; EXPECT_EQ(8, snprintf(buf, sizeof(buf), "<%ls>", ws)); EXPECT_STREQ("<(null)>", buf); wchar_t chars[] = { L'h', L'i', 0 }; ws = chars; EXPECT_EQ(4, snprintf(buf, sizeof(buf), "<%ls>", ws)); EXPECT_STREQ("<hi>", buf); } TEST(STDIO_TEST, snprintf_S) { // Synonym for %ls. char buf[BUFSIZ]; wchar_t* ws = nullptr; EXPECT_EQ(8, snprintf(buf, sizeof(buf), "<%S>", ws)); EXPECT_STREQ("<(null)>", buf); wchar_t chars[] = { L'h', L'i', 0 }; ws = chars; EXPECT_EQ(4, snprintf(buf, sizeof(buf), "<%S>", ws)); EXPECT_STREQ("<hi>", buf); } TEST(STDIO_TEST, snprintf_n) { #if defined(__BIONIC__) // http://b/14492135 and http://b/31832608. char buf[32]; int i = 1234; EXPECT_DEATH(snprintf(buf, sizeof(buf), "a %n b", &i), "%n not allowed on Android"); #else GTEST_SKIP() << "glibc does allow %n"; #endif } TEST(STDIO_TEST, snprintf_smoke) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "a"); EXPECT_STREQ("a", buf); snprintf(buf, sizeof(buf), "%%"); EXPECT_STREQ("%", buf); snprintf(buf, sizeof(buf), "01234"); EXPECT_STREQ("01234", buf); snprintf(buf, sizeof(buf), "a%sb", "01234"); EXPECT_STREQ("a01234b", buf); char* s = nullptr; snprintf(buf, sizeof(buf), "a%sb", s); EXPECT_STREQ("a(null)b", buf); snprintf(buf, sizeof(buf), "aa%scc", "bb"); EXPECT_STREQ("aabbcc", buf); snprintf(buf, sizeof(buf), "a%cc", 'b'); EXPECT_STREQ("abc", buf); snprintf(buf, sizeof(buf), "a%db", 1234); EXPECT_STREQ("a1234b", buf); snprintf(buf, sizeof(buf), "a%db", -8123); EXPECT_STREQ("a-8123b", buf); snprintf(buf, sizeof(buf), "a%hdb", static_cast<short>(0x7fff0010)); EXPECT_STREQ("a16b", buf); snprintf(buf, sizeof(buf), "a%hhdb", static_cast<char>(0x7fffff10)); EXPECT_STREQ("a16b", buf); snprintf(buf, sizeof(buf), "a%lldb", 0x1000000000LL); EXPECT_STREQ("a68719476736b", buf); snprintf(buf, sizeof(buf), "a%ldb", 70000L); EXPECT_STREQ("a70000b", buf); snprintf(buf, sizeof(buf), "a%pb", reinterpret_cast<void*>(0xb0001234)); EXPECT_STREQ("a0xb0001234b", buf); snprintf(buf, sizeof(buf), "a%xz", 0x12ab); EXPECT_STREQ("a12abz", buf); snprintf(buf, sizeof(buf), "a%Xz", 0x12ab); EXPECT_STREQ("a12ABz", buf); snprintf(buf, sizeof(buf), "a%08xz", 0x123456); EXPECT_STREQ("a00123456z", buf); snprintf(buf, sizeof(buf), "a%5dz", 1234); EXPECT_STREQ("a 1234z", buf); snprintf(buf, sizeof(buf), "a%05dz", 1234); EXPECT_STREQ("a01234z", buf); snprintf(buf, sizeof(buf), "a%8dz", 1234); EXPECT_STREQ("a 1234z", buf); snprintf(buf, sizeof(buf), "a%-8dz", 1234); EXPECT_STREQ("a1234 z", buf); snprintf(buf, sizeof(buf), "A%-11sZ", "abcdef"); EXPECT_STREQ("Aabcdef Z", buf); snprintf(buf, sizeof(buf), "A%s:%dZ", "hello", 1234); EXPECT_STREQ("Ahello:1234Z", buf); snprintf(buf, sizeof(buf), "a%03d:%d:%02dz", 5, 5, 5); EXPECT_STREQ("a005:5:05z", buf); void* p = nullptr; snprintf(buf, sizeof(buf), "a%d,%pz", 5, p); #if defined(__BIONIC__) EXPECT_STREQ("a5,0x0z", buf); #else // __BIONIC__ EXPECT_STREQ("a5,(nil)z", buf); #endif // __BIONIC__ snprintf(buf, sizeof(buf), "a%lld,%d,%d,%dz", 0x1000000000LL, 6, 7, 8); EXPECT_STREQ("a68719476736,6,7,8z", buf); snprintf(buf, sizeof(buf), "a_%f_b", 1.23f); EXPECT_STREQ("a_1.230000_b", buf); snprintf(buf, sizeof(buf), "a_%g_b", 3.14); EXPECT_STREQ("a_3.14_b", buf); snprintf(buf, sizeof(buf), "%1$s %1$s", "print_me_twice"); EXPECT_STREQ("print_me_twice print_me_twice", buf); } template <typename T> static void CheckInfNan(int snprintf_fn(T*, size_t, const T*, ...), int sscanf_fn(const T*, const T*, ...), const T* fmt_string, const T* fmt, const T* fmt_plus, const T* minus_inf, const T* inf_, const T* plus_inf, const T* minus_nan, const T* nan_, const T* plus_nan) { T buf[BUFSIZ]; float f; // NaN. snprintf_fn(buf, sizeof(buf), fmt, nanf("")); EXPECT_STREQ(nan_, buf) << fmt; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_TRUE(isnan(f)); snprintf_fn(buf, sizeof(buf), fmt, -nanf("")); EXPECT_STREQ(minus_nan, buf) << fmt; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_TRUE(isnan(f)); snprintf_fn(buf, sizeof(buf), fmt_plus, nanf("")); EXPECT_STREQ(plus_nan, buf) << fmt_plus; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_TRUE(isnan(f)); snprintf_fn(buf, sizeof(buf), fmt_plus, -nanf("")); EXPECT_STREQ(minus_nan, buf) << fmt_plus; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_TRUE(isnan(f)); // Inf. snprintf_fn(buf, sizeof(buf), fmt, HUGE_VALF); EXPECT_STREQ(inf_, buf) << fmt; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_EQ(HUGE_VALF, f); snprintf_fn(buf, sizeof(buf), fmt, -HUGE_VALF); EXPECT_STREQ(minus_inf, buf) << fmt; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_EQ(-HUGE_VALF, f); snprintf_fn(buf, sizeof(buf), fmt_plus, HUGE_VALF); EXPECT_STREQ(plus_inf, buf) << fmt_plus; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_EQ(HUGE_VALF, f); snprintf_fn(buf, sizeof(buf), fmt_plus, -HUGE_VALF); EXPECT_STREQ(minus_inf, buf) << fmt_plus; EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)); EXPECT_EQ(-HUGE_VALF, f); // Check case-insensitivity. snprintf_fn(buf, sizeof(buf), fmt_string, "[InFiNiTy]"); EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)) << buf; EXPECT_EQ(HUGE_VALF, f); snprintf_fn(buf, sizeof(buf), fmt_string, "[NaN]"); EXPECT_EQ(1, sscanf_fn(buf, fmt, &f)) << buf; EXPECT_TRUE(isnan(f)); } TEST(STDIO_TEST, snprintf_sscanf_inf_nan) { CheckInfNan(snprintf, sscanf, "%s", "[%a]", "[%+a]", "[-inf]", "[inf]", "[+inf]", "[-nan]", "[nan]", "[+nan]"); CheckInfNan(snprintf, sscanf, "%s", "[%A]", "[%+A]", "[-INF]", "[INF]", "[+INF]", "[-NAN]", "[NAN]", "[+NAN]"); CheckInfNan(snprintf, sscanf, "%s", "[%e]", "[%+e]", "[-inf]", "[inf]", "[+inf]", "[-nan]", "[nan]", "[+nan]"); CheckInfNan(snprintf, sscanf, "%s", "[%E]", "[%+E]", "[-INF]", "[INF]", "[+INF]", "[-NAN]", "[NAN]", "[+NAN]"); CheckInfNan(snprintf, sscanf, "%s", "[%f]", "[%+f]", "[-inf]", "[inf]", "[+inf]", "[-nan]", "[nan]", "[+nan]"); CheckInfNan(snprintf, sscanf, "%s", "[%F]", "[%+F]", "[-INF]", "[INF]", "[+INF]", "[-NAN]", "[NAN]", "[+NAN]"); CheckInfNan(snprintf, sscanf, "%s", "[%g]", "[%+g]", "[-inf]", "[inf]", "[+inf]", "[-nan]", "[nan]", "[+nan]"); CheckInfNan(snprintf, sscanf, "%s", "[%G]", "[%+G]", "[-INF]", "[INF]", "[+INF]", "[-NAN]", "[NAN]", "[+NAN]"); } TEST(STDIO_TEST, swprintf_swscanf_inf_nan) { CheckInfNan(swprintf, swscanf, L"%s", L"[%a]", L"[%+a]", L"[-inf]", L"[inf]", L"[+inf]", L"[-nan]", L"[nan]", L"[+nan]"); CheckInfNan(swprintf, swscanf, L"%s", L"[%A]", L"[%+A]", L"[-INF]", L"[INF]", L"[+INF]", L"[-NAN]", L"[NAN]", L"[+NAN]"); CheckInfNan(swprintf, swscanf, L"%s", L"[%e]", L"[%+e]", L"[-inf]", L"[inf]", L"[+inf]", L"[-nan]", L"[nan]", L"[+nan]"); CheckInfNan(swprintf, swscanf, L"%s", L"[%E]", L"[%+E]", L"[-INF]", L"[INF]", L"[+INF]", L"[-NAN]", L"[NAN]", L"[+NAN]"); CheckInfNan(swprintf, swscanf, L"%s", L"[%f]", L"[%+f]", L"[-inf]", L"[inf]", L"[+inf]", L"[-nan]", L"[nan]", L"[+nan]"); CheckInfNan(swprintf, swscanf, L"%s", L"[%F]", L"[%+F]", L"[-INF]", L"[INF]", L"[+INF]", L"[-NAN]", L"[NAN]", L"[+NAN]"); CheckInfNan(swprintf, swscanf, L"%s", L"[%g]", L"[%+g]", L"[-inf]", L"[inf]", L"[+inf]", L"[-nan]", L"[nan]", L"[+nan]"); CheckInfNan(swprintf, swscanf, L"%s", L"[%G]", L"[%+G]", L"[-INF]", L"[INF]", L"[+INF]", L"[-NAN]", L"[NAN]", L"[+NAN]"); } TEST(STDIO_TEST, swprintf) { constexpr size_t nchars = 32; wchar_t buf[nchars]; ASSERT_EQ(2, swprintf(buf, nchars, L"ab")) << strerror(errno); ASSERT_EQ(std::wstring(L"ab"), buf); ASSERT_EQ(5, swprintf(buf, nchars, L"%s", "abcde")); ASSERT_EQ(std::wstring(L"abcde"), buf); // Unlike swprintf(), swprintf() returns -1 in case of truncation // and doesn't necessarily zero-terminate the output! ASSERT_EQ(-1, swprintf(buf, 4, L"%s", "abcde")); const char kString[] = "Hello, World"; ASSERT_EQ(12, swprintf(buf, nchars, L"%s", kString)); ASSERT_EQ(std::wstring(L"Hello, World"), buf); ASSERT_EQ(12, swprintf(buf, 13, L"%s", kString)); ASSERT_EQ(std::wstring(L"Hello, World"), buf); } TEST(STDIO_TEST, swprintf_a) { constexpr size_t nchars = 32; wchar_t buf[nchars]; ASSERT_EQ(20, swprintf(buf, nchars, L"%a", 3.1415926535)); ASSERT_EQ(std::wstring(L"0x1.921fb54411744p+1"), buf); } TEST(STDIO_TEST, swprintf_lc) { constexpr size_t nchars = 32; wchar_t buf[nchars]; wint_t wc = L'a'; EXPECT_EQ(3, swprintf(buf, nchars, L"<%lc>", wc)); EXPECT_EQ(std::wstring(L"<a>"), buf); } TEST(STDIO_TEST, swprintf_C) { // Synonym for %lc. constexpr size_t nchars = 32; wchar_t buf[nchars]; wint_t wc = L'a'; EXPECT_EQ(3, swprintf(buf, nchars, L"<%C>", wc)); EXPECT_EQ(std::wstring(L"<a>"), buf); } TEST(STDIO_TEST, swprintf_jd_INTMAX_MAX) { constexpr size_t nchars = 32; wchar_t buf[nchars]; swprintf(buf, nchars, L"%jd", INTMAX_MAX); EXPECT_EQ(std::wstring(L"9223372036854775807"), buf); } TEST(STDIO_TEST, swprintf_jd_INTMAX_MIN) { constexpr size_t nchars = 32; wchar_t buf[nchars]; swprintf(buf, nchars, L"%jd", INTMAX_MIN); EXPECT_EQ(std::wstring(L"-9223372036854775808"), buf); } TEST(STDIO_TEST, swprintf_ju_UINTMAX_MAX) { constexpr size_t nchars = 32; wchar_t buf[nchars]; swprintf(buf, nchars, L"%ju", UINTMAX_MAX); EXPECT_EQ(std::wstring(L"18446744073709551615"), buf); } TEST(STDIO_TEST, swprintf_1$ju_UINTMAX_MAX) { constexpr size_t nchars = 32; wchar_t buf[nchars]; swprintf(buf, nchars, L"%1$ju", UINTMAX_MAX); EXPECT_EQ(std::wstring(L"18446744073709551615"), buf); } TEST(STDIO_TEST, swprintf_ls) { constexpr size_t nchars = 32; wchar_t buf[nchars]; static const wchar_t kWideString[] = L"Hello\uff41 World"; ASSERT_EQ(12, swprintf(buf, nchars, L"%ls", kWideString)); ASSERT_EQ(std::wstring(kWideString), buf); ASSERT_EQ(12, swprintf(buf, 13, L"%ls", kWideString)); ASSERT_EQ(std::wstring(kWideString), buf); } TEST(STDIO_TEST, swprintf_S) { // Synonym for %ls. constexpr size_t nchars = 32; wchar_t buf[nchars]; static const wchar_t kWideString[] = L"Hello\uff41 World"; ASSERT_EQ(12, swprintf(buf, nchars, L"%S", kWideString)); ASSERT_EQ(std::wstring(kWideString), buf); ASSERT_EQ(12, swprintf(buf, 13, L"%S", kWideString)); ASSERT_EQ(std::wstring(kWideString), buf); } TEST(STDIO_TEST, snprintf_d_INT_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%d", INT_MAX); EXPECT_STREQ("2147483647", buf); } TEST(STDIO_TEST, snprintf_d_INT_MIN) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%d", INT_MIN); EXPECT_STREQ("-2147483648", buf); } TEST(STDIO_TEST, snprintf_jd_INTMAX_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%jd", INTMAX_MAX); EXPECT_STREQ("9223372036854775807", buf); } TEST(STDIO_TEST, snprintf_jd_INTMAX_MIN) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%jd", INTMAX_MIN); EXPECT_STREQ("-9223372036854775808", buf); } TEST(STDIO_TEST, snprintf_ju_UINTMAX_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%ju", UINTMAX_MAX); EXPECT_STREQ("18446744073709551615", buf); } TEST(STDIO_TEST, snprintf_1$ju_UINTMAX_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%1$ju", UINTMAX_MAX); EXPECT_STREQ("18446744073709551615", buf); } TEST(STDIO_TEST, snprintf_ld_LONG_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%ld", LONG_MAX); #if defined(__LP64__) EXPECT_STREQ("9223372036854775807", buf); #else EXPECT_STREQ("2147483647", buf); #endif } TEST(STDIO_TEST, snprintf_ld_LONG_MIN) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%ld", LONG_MIN); #if defined(__LP64__) EXPECT_STREQ("-9223372036854775808", buf); #else EXPECT_STREQ("-2147483648", buf); #endif } TEST(STDIO_TEST, snprintf_lld_LLONG_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%lld", LLONG_MAX); EXPECT_STREQ("9223372036854775807", buf); } TEST(STDIO_TEST, snprintf_lld_LLONG_MIN) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%lld", LLONG_MIN); EXPECT_STREQ("-9223372036854775808", buf); } TEST(STDIO_TEST, snprintf_o_UINT_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%o", UINT_MAX); EXPECT_STREQ("37777777777", buf); } TEST(STDIO_TEST, snprintf_u_UINT_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%u", UINT_MAX); EXPECT_STREQ("4294967295", buf); } TEST(STDIO_TEST, snprintf_x_UINT_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%x", UINT_MAX); EXPECT_STREQ("ffffffff", buf); } TEST(STDIO_TEST, snprintf_X_UINT_MAX) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%X", UINT_MAX); EXPECT_STREQ("FFFFFFFF", buf); } TEST(STDIO_TEST, snprintf_e) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%e", 1.5); EXPECT_STREQ("1.500000e+00", buf); snprintf(buf, sizeof(buf), "%Le", 1.5L); EXPECT_STREQ("1.500000e+00", buf); } TEST(STDIO_TEST, snprintf_negative_zero_5084292) { char buf[BUFSIZ]; snprintf(buf, sizeof(buf), "%e", -0.0); EXPECT_STREQ("-0.000000e+00", buf); snprintf(buf, sizeof(buf), "%E", -0.0); EXPECT_STREQ("-0.000000E+00", buf); snprintf(buf, sizeof(buf), "%f", -0.0); EXPECT_STREQ("-0.000000", buf); snprintf(buf, sizeof(buf), "%F", -0.0); EXPECT_STREQ("-0.000000", buf); snprintf(buf, sizeof(buf), "%g", -0.0); EXPECT_STREQ("-0", buf); snprintf(buf, sizeof(buf), "%G", -0.0); EXPECT_STREQ("-0", buf); snprintf(buf, sizeof(buf), "%a", -0.0); EXPECT_STREQ("-0x0p+0", buf); snprintf(buf, sizeof(buf), "%A", -0.0); EXPECT_STREQ("-0X0P+0", buf); } TEST(STDIO_TEST, snprintf_utf8_15439554) { locale_t cloc = newlocale(LC_ALL, "C.UTF-8", nullptr); locale_t old_locale = uselocale(cloc); // http://b/15439554 char buf[BUFSIZ]; // 1-byte character. snprintf(buf, sizeof(buf), "%dx%d", 1, 2); EXPECT_STREQ("1x2", buf); // 2-byte character. snprintf(buf, sizeof(buf), "%d\xc2\xa2%d", 1, 2); EXPECT_STREQ("1¢2", buf); // 3-byte character. snprintf(buf, sizeof(buf), "%d\xe2\x82\xac%d", 1, 2); EXPECT_STREQ("1€2", buf); // 4-byte character. snprintf(buf, sizeof(buf), "%d\xf0\xa4\xad\xa2%d", 1, 2); EXPECT_STREQ("1𤭢2", buf); uselocale(old_locale); freelocale(cloc); } static void* snprintf_small_stack_fn(void*) { // Make life (realistically) hard for ourselves by allocating our own buffer for the result. char buf[PATH_MAX]; snprintf(buf, sizeof(buf), "/proc/%d", getpid()); return nullptr; } TEST(STDIO_TEST, snprintf_small_stack) { // Is it safe to call snprintf on a thread with a small stack? // (The snprintf implementation puts some pretty large buffers on the stack.) pthread_attr_t a; ASSERT_EQ(0, pthread_attr_init(&a)); ASSERT_EQ(0, pthread_attr_setstacksize(&a, PTHREAD_STACK_MIN)); pthread_t t; ASSERT_EQ(0, pthread_create(&t, &a, snprintf_small_stack_fn, nullptr)); ASSERT_EQ(0, pthread_join(t, nullptr)); } TEST(STDIO_TEST, snprintf_asterisk_overflow) { char buf[128]; ASSERT_EQ(5, snprintf(buf, sizeof(buf), "%.*s%c", 4, "hello world", '!')); ASSERT_EQ(12, snprintf(buf, sizeof(buf), "%.*s%c", INT_MAX/2, "hello world", '!')); ASSERT_EQ(12, snprintf(buf, sizeof(buf), "%.*s%c", INT_MAX-1, "hello world", '!')); ASSERT_EQ(12, snprintf(buf, sizeof(buf), "%.*s%c", INT_MAX, "hello world", '!')); ASSERT_EQ(12, snprintf(buf, sizeof(buf), "%.*s%c", -1, "hello world", '!')); // INT_MAX-1, INT_MAX, INT_MAX+1. ASSERT_EQ(12, snprintf(buf, sizeof(buf), "%.2147483646s%c", "hello world", '!')); ASSERT_EQ(12, snprintf(buf, sizeof(buf), "%.2147483647s%c", "hello world", '!')); ASSERT_EQ(-1, snprintf(buf, sizeof(buf), "%.2147483648s%c", "hello world", '!')); ASSERT_EQ(ENOMEM, errno); } TEST(STDIO_TEST, fprintf) { TemporaryFile tf; FILE* tfile = fdopen(tf.fd, "r+"); ASSERT_TRUE(tfile != nullptr); ASSERT_EQ(7, fprintf(tfile, "%d %s", 123, "abc")); AssertFileIs(tfile, "123 abc"); fclose(tfile); } TEST(STDIO_TEST, fprintf_failures_7229520) { // http://b/7229520 FILE* fp; int fd_rdonly = open("/dev/null", O_RDONLY); ASSERT_NE(-1, fd_rdonly); // Unbuffered case where the fprintf(3) itself fails. ASSERT_NE(nullptr, fp = tmpfile()); setbuf(fp, nullptr); ASSERT_EQ(4, fprintf(fp, "epic")); ASSERT_NE(-1, dup2(fd_rdonly, fileno(fp))); ASSERT_EQ(-1, fprintf(fp, "fail")); ASSERT_EQ(0, fclose(fp)); // Buffered case where we won't notice until the fclose(3). // It's likely this is what was actually seen in http://b/7229520, // and that expecting fprintf to fail is setting yourself up for // disappointment. Remember to check fclose(3)'s return value, kids! ASSERT_NE(nullptr, fp = tmpfile()); ASSERT_EQ(4, fprintf(fp, "epic")); ASSERT_NE(-1, dup2(fd_rdonly, fileno(fp))); ASSERT_EQ(4, fprintf(fp, "fail")); ASSERT_EQ(-1, fclose(fp)); } TEST(STDIO_TEST, popen_r) { FILE* fp = popen("cat /proc/version", "r"); ASSERT_TRUE(fp != nullptr); char buf[16]; char* s = fgets(buf, sizeof(buf), fp); buf[13] = '\0'; ASSERT_STREQ("Linux version", s); ASSERT_EQ(0, pclose(fp)); } TEST(STDIO_TEST, popen_socketpair) { FILE* fp = popen("cat", "r+"); ASSERT_TRUE(fp != nullptr); fputs("hello\nworld\n", fp); fflush(fp); char buf[16]; ASSERT_NE(nullptr, fgets(buf, sizeof(buf), fp)); EXPECT_STREQ("hello\n", buf); ASSERT_NE(nullptr, fgets(buf, sizeof(buf), fp)); EXPECT_STREQ("world\n", buf); ASSERT_EQ(0, pclose(fp)); } TEST(STDIO_TEST, popen_socketpair_shutdown) { FILE* fp = popen("uniq -c", "r+"); ASSERT_TRUE(fp != nullptr); fputs("a\na\na\na\nb\n", fp); fflush(fp); ASSERT_EQ(0, shutdown(fileno(fp), SHUT_WR)); char buf[16]; ASSERT_NE(nullptr, fgets(buf, sizeof(buf), fp)); EXPECT_STREQ(" 4 a\n", buf); ASSERT_NE(nullptr, fgets(buf, sizeof(buf), fp)); EXPECT_STREQ(" 1 b\n", buf); ASSERT_EQ(0, pclose(fp)); } TEST(STDIO_TEST, popen_return_value_0) { FILE* fp = popen("true", "r"); ASSERT_TRUE(fp != nullptr); int status = pclose(fp); EXPECT_TRUE(WIFEXITED(status)); EXPECT_EQ(0, WEXITSTATUS(status)); } TEST(STDIO_TEST, popen_return_value_1) { FILE* fp = popen("false", "r"); ASSERT_TRUE(fp != nullptr); int status = pclose(fp); EXPECT_TRUE(WIFEXITED(status)); EXPECT_EQ(1, WEXITSTATUS(status)); } TEST(STDIO_TEST, popen_return_value_signal) { FILE* fp = popen("kill -7 $$", "r"); ASSERT_TRUE(fp != nullptr); int status = pclose(fp); EXPECT_TRUE(WIFSIGNALED(status)); EXPECT_EQ(7, WTERMSIG(status)); } TEST(STDIO_TEST, getc) { FILE* fp = fopen("/proc/version", "r"); ASSERT_TRUE(fp != nullptr); ASSERT_EQ('L', getc(fp)); ASSERT_EQ('i', getc(fp)); ASSERT_EQ('n', getc(fp)); ASSERT_EQ('u', getc(fp)); ASSERT_EQ('x', getc(fp)); fclose(fp); } TEST(STDIO_TEST, putc) { FILE* fp = fopen("/proc/version", "r"); ASSERT_TRUE(fp != nullptr); ASSERT_EQ(EOF, putc('x', fp)); fclose(fp); } TEST(STDIO_TEST, sscanf_swscanf) { struct stuff { char s1[123]; int i1, i2; char cs1[3]; char s2[3]; char c1; double d1; float f1; char s3[123]; void Check() { EXPECT_STREQ("hello", s1); EXPECT_EQ(123, i1); EXPECT_EQ(456, i2); EXPECT_EQ('a', cs1[0]); EXPECT_EQ('b', cs1[1]); EXPECT_EQ('x', cs1[2]); // No terminating NUL. EXPECT_STREQ("AB", s2); // Terminating NUL. EXPECT_EQ('!', c1); EXPECT_DOUBLE_EQ(1.23, d1); EXPECT_FLOAT_EQ(9.0f, f1); EXPECT_STREQ("world", s3); } } s; memset(&s, 'x', sizeof(s)); ASSERT_EQ(9, sscanf(" hello 123 456abAB! 1.23 0x1.2p3 world", "%s %i%i%2c%[A-Z]%c %lf %f %s", s.s1, &s.i1, &s.i2, s.cs1, s.s2, &s.c1, &s.d1, &s.f1, s.s3)); s.Check(); memset(&s, 'x', sizeof(s)); ASSERT_EQ(9, swscanf(L" hello 123 456abAB! 1.23 0x1.2p3 world", L"%s %i%i%2c%[A-Z]%c %lf %f %s", s.s1, &s.i1, &s.i2, s.cs1, s.s2, &s.c1, &s.d1, &s.f1, s.s3)); s.Check(); } template <typename T> static void CheckScanf(int sscanf_fn(const T*, const T*, ...), const T* input, const T* fmt, int expected_count, const char* expected_string) { char buf[256] = {}; ASSERT_EQ(expected_count, sscanf_fn(input, fmt, &buf)) << fmt; ASSERT_STREQ(expected_string, buf) << fmt; } TEST(STDIO_TEST, sscanf_ccl) { // `abc` is just those characters. CheckScanf(sscanf, "abcd", "%[abc]", 1, "abc"); // `a-c` is the range 'a' .. 'c'. CheckScanf(sscanf, "abcd", "%[a-c]", 1, "abc"); CheckScanf(sscanf, "-d", "%[a-c]", 0, ""); CheckScanf(sscanf, "ac-bAd", "%[a--c]", 1, "ac-bA"); // `a-c-e` is equivalent to `a-e`. CheckScanf(sscanf, "abcdefg", "%[a-c-e]", 1, "abcde"); // `e-a` is equivalent to `ae-` (because 'e' > 'a'). CheckScanf(sscanf, "-a-e-b", "%[e-a]", 1, "-a-e-"); // An initial '^' negates the set. CheckScanf(sscanf, "abcde", "%[^d]", 1, "abc"); CheckScanf(sscanf, "abcdefgh", "%[^c-d]", 1, "ab"); CheckScanf(sscanf, "hgfedcba", "%[^c-d]", 1, "hgfe"); // The first character may be ']' or '-' without being special. CheckScanf(sscanf, "[[]]x", "%[][]", 1, "[[]]"); CheckScanf(sscanf, "-a-x", "%[-a]", 1, "-a-"); // The last character may be '-' without being special. CheckScanf(sscanf, "-a-x", "%[a-]", 1, "-a-"); // X--Y is [X--] + Y, not [X--] + [--Y] (a bug in my initial implementation). CheckScanf(sscanf, "+,-/.", "%[+--/]", 1, "+,-/"); } TEST(STDIO_TEST, swscanf_ccl) { // `abc` is just those characters. CheckScanf(swscanf, L"abcd", L"%[abc]", 1, "abc"); // `a-c` is the range 'a' .. 'c'. CheckScanf(swscanf, L"abcd", L"%[a-c]", 1, "abc"); CheckScanf(swscanf, L"-d", L"%[a-c]", 0, ""); CheckScanf(swscanf, L"ac-bAd", L"%[a--c]", 1, "ac-bA"); // `a-c-e` is equivalent to `a-e`. CheckScanf(swscanf, L"abcdefg", L"%[a-c-e]", 1, "abcde"); // `e-a` is equivalent to `ae-` (because 'e' > 'a'). CheckScanf(swscanf, L"-a-e-b", L"%[e-a]", 1, "-a-e-"); // An initial '^' negates the set. CheckScanf(swscanf, L"abcde", L"%[^d]", 1, "abc"); CheckScanf(swscanf, L"abcdefgh", L"%[^c-d]", 1, "ab"); CheckScanf(swscanf, L"hgfedcba", L"%[^c-d]", 1, "hgfe"); // The first character may be ']' or '-' without being special. CheckScanf(swscanf, L"[[]]x", L"%[][]", 1, "[[]]"); CheckScanf(swscanf, L"-a-x", L"%[-a]", 1, "-a-"); // The last character may be '-' without being special. CheckScanf(swscanf, L"-a-x", L"%[a-]", 1, "-a-"); // X--Y is [X--] + Y, not [X--] + [--Y] (a bug in my initial implementation). CheckScanf(swscanf, L"+,-/.", L"%[+--/]", 1, "+,-/"); } template <typename T1, typename T2> static void CheckScanfM(int sscanf_fn(const T1*, const T1*, ...), const T1* input, const T1* fmt, int expected_count, const T2* expected_string) { T2* result = nullptr; ASSERT_EQ(expected_count, sscanf_fn(input, fmt, &result)) << fmt; if (expected_string == nullptr) { ASSERT_EQ(nullptr, result); } else { ASSERT_STREQ(expected_string, result) << fmt; } free(result); } TEST(STDIO_TEST, sscanf_mc) { char* p1 = nullptr; char* p2 = nullptr; ASSERT_EQ(2, sscanf("hello", "%mc%mc", &p1, &p2)); ASSERT_EQ('h', *p1); ASSERT_EQ('e', *p2); free(p1); free(p2); p1 = nullptr; ASSERT_EQ(1, sscanf("hello", "%4mc", &p1)); ASSERT_EQ('h', p1[0]); ASSERT_EQ('e', p1[1]); ASSERT_EQ('l', p1[2]); ASSERT_EQ('l', p1[3]); free(p1); p1 = nullptr; ASSERT_EQ(1, sscanf("hello world", "%30mc", &p1)); ASSERT_EQ('h', p1[0]); ASSERT_EQ('e', p1[1]); ASSERT_EQ('l', p1[2]); ASSERT_EQ('l', p1[3]); ASSERT_EQ('o', p1[4]); free(p1); } TEST(STDIO_TEST, sscanf_mlc) { // This is so useless that clang doesn't even believe it exists... #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wformat-invalid-specifier" #pragma clang diagnostic ignored "-Wformat-extra-args" wchar_t* p1 = nullptr; wchar_t* p2 = nullptr; ASSERT_EQ(2, sscanf("hello", "%mlc%mlc", &p1, &p2)); ASSERT_EQ(L'h', *p1); ASSERT_EQ(L'e', *p2); free(p1); free(p2); p1 = nullptr; ASSERT_EQ(1, sscanf("hello", "%4mlc", &p1)); ASSERT_EQ(L'h', p1[0]); ASSERT_EQ(L'e', p1[1]); ASSERT_EQ(L'l', p1[2]); ASSERT_EQ(L'l', p1[3]); free(p1); p1 = nullptr; ASSERT_EQ(1, sscanf("hello world", "%30mlc", &p1)); ASSERT_EQ(L'h', p1[0]); ASSERT_EQ(L'e', p1[1]); ASSERT_EQ(L'l', p1[2]); ASSERT_EQ(L'l', p1[3]); ASSERT_EQ(L'o', p1[4]); free(p1); #pragma clang diagnostic pop } TEST(STDIO_TEST, sscanf_ms) { CheckScanfM(sscanf, "hello", "%ms", 1, "hello"); CheckScanfM(sscanf, "hello", "%4ms", 1, "hell"); CheckScanfM(sscanf, "hello world", "%30ms", 1, "hello"); } TEST(STDIO_TEST, sscanf_mls) { CheckScanfM(sscanf, "hello", "%mls", 1, L"hello"); CheckScanfM(sscanf, "hello", "%4mls", 1, L"hell"); CheckScanfM(sscanf, "hello world", "%30mls", 1, L"hello"); } TEST(STDIO_TEST, sscanf_m_ccl) { CheckScanfM(sscanf, "hello", "%m[a-z]", 1, "hello"); CheckScanfM(sscanf, "hello", "%4m[a-z]", 1, "hell"); CheckScanfM(sscanf, "hello world", "%30m[a-z]", 1, "hello"); } TEST(STDIO_TEST, sscanf_ml_ccl) { CheckScanfM(sscanf, "hello", "%ml[a-z]", 1, L"hello"); CheckScanfM(sscanf, "hello", "%4ml[a-z]", 1, L"hell"); CheckScanfM(sscanf, "hello world", "%30ml[a-z]", 1, L"hello"); } TEST(STDIO_TEST, sscanf_ls) { wchar_t w[32] = {}; ASSERT_EQ(1, sscanf("hello world", "%ls", w)); ASSERT_EQ(L"hello", std::wstring(w)); } TEST(STDIO_TEST, sscanf_ls_suppress) { ASSERT_EQ(0, sscanf("hello world", "%*ls %*ls")); } TEST(STDIO_TEST, sscanf_ls_n) { setlocale(LC_ALL, "C.UTF-8"); wchar_t w[32] = {}; int pos = 0; ASSERT_EQ(1, sscanf("\xc4\x80", "%ls%n", w, &pos)); ASSERT_EQ(static_cast<wchar_t>(256), w[0]); ASSERT_EQ(2, pos); } TEST(STDIO_TEST, sscanf_ls_realloc) { // This is so useless that clang doesn't even believe it exists... #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wformat-invalid-specifier" #pragma clang diagnostic ignored "-Wformat-extra-args" wchar_t* p1 = nullptr; wchar_t* p2 = nullptr; ASSERT_EQ(2, sscanf("1234567890123456789012345678901234567890 world", "%mls %mls", &p1, &p2)); ASSERT_EQ(L"1234567890123456789012345678901234567890", std::wstring(p1)); ASSERT_EQ(L"world", std::wstring(p2)); #pragma clang diagnostic pop } // https://bugs.freebsd.org/bugzilla/show_bug.cgi?id=202240 TEST(STDIO_TEST, scanf_wscanf_EOF) { EXPECT_EQ(0, sscanf("b", "ab")); EXPECT_EQ(EOF, sscanf("", "a")); EXPECT_EQ(0, swscanf(L"b", L"ab")); EXPECT_EQ(EOF, swscanf(L"", L"a")); } TEST(STDIO_TEST, scanf_invalid_UTF8) { #if 0 // TODO: more tests invented during code review; no regressions, so fix later. char buf[BUFSIZ]; wchar_t wbuf[BUFSIZ]; memset(buf, 0, sizeof(buf)); memset(wbuf, 0, sizeof(wbuf)); EXPECT_EQ(0, sscanf("\xc0" " foo", "%ls %s", wbuf, buf)); #endif } TEST(STDIO_TEST, scanf_no_match_no_termination) { char buf[4] = "x"; EXPECT_EQ(0, sscanf("d", "%[abc]", buf)); EXPECT_EQ('x', buf[0]); EXPECT_EQ(0, swscanf(L"d", L"%[abc]", buf)); EXPECT_EQ('x', buf[0]); wchar_t wbuf[4] = L"x"; EXPECT_EQ(0, swscanf(L"d", L"%l[abc]", wbuf)); EXPECT_EQ(L'x', wbuf[0]); EXPECT_EQ(EOF, sscanf("", "%s", buf)); EXPECT_EQ('x', buf[0]); EXPECT_EQ(EOF, swscanf(L"", L"%ls", wbuf)); EXPECT_EQ(L'x', wbuf[0]); } TEST(STDIO_TEST, scanf_wscanf_wide_character_class) { #if 0 // TODO: more tests invented during code review; no regressions, so fix later. wchar_t buf[BUFSIZ]; // A wide character shouldn't match an ASCII-only class for scanf or wscanf. memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, sscanf("xĀyz", "%l[xy]", buf)); EXPECT_EQ(L"x"s, std::wstring(buf)); memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, swscanf(L"xĀyz", L"%l[xy]", buf)); EXPECT_EQ(L"x"s, std::wstring(buf)); // Even if scanf has wide characters in a class, they won't match... // TODO: is that a bug? memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, sscanf("xĀyz", "%l[xĀy]", buf)); EXPECT_EQ(L"x"s, std::wstring(buf)); // ...unless you use wscanf. memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, swscanf(L"xĀyz", L"%l[xĀy]", buf)); EXPECT_EQ(L"xĀy"s, std::wstring(buf)); // Negation only covers ASCII for scanf... memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, sscanf("xĀyz", "%l[^ab]", buf)); EXPECT_EQ(L"x"s, std::wstring(buf)); // ...but covers wide characters for wscanf. memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, swscanf(L"xĀyz", L"%l[^ab]", buf)); EXPECT_EQ(L"xĀyz"s, std::wstring(buf)); // We already determined that non-ASCII characters are ignored in scanf classes. memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, sscanf("x" "\xc4\x80" // Matches a byte from each wide char in the class. "\xc6\x82" // Neither byte is in the class. "yz", "%l[xy" "\xc5\x80" "\xc4\x81" "]", buf)); EXPECT_EQ(L"x", std::wstring(buf)); // bionic and glibc both behave badly for wscanf, so let's call it right for now... memset(buf, 0, sizeof(buf)); EXPECT_EQ(1, swscanf(L"x" L"\xc4\x80" L"\xc6\x82" L"yz", L"%l[xy" L"\xc5\x80" L"\xc4\x81" L"]", buf)); // Note that this isn't L"xĀ" --- although the *bytes* matched, they're // not put back together as a wide character. EXPECT_EQ(L"x" L"\xc4" L"\x80", std::wstring(buf)); #endif } TEST(STDIO_TEST, cantwrite_EBADF) { // If we open a file read-only... FILE* fp = fopen("/proc/version", "r"); // ...all attempts to write to that file should return failure. // They should also set errno to EBADF. This isn't POSIX, but it's traditional. // glibc gets the wide-character functions wrong. errno = 0; EXPECT_EQ(EOF, putc('x', fp)); EXPECT_EQ(EBADF, errno); errno = 0; EXPECT_EQ(EOF, fprintf(fp, "hello")); EXPECT_EQ(EBADF, errno); errno = 0; EXPECT_EQ(EOF, fwprintf(fp, L"hello")); #if defined(__BIONIC__) EXPECT_EQ(EBADF, errno); #endif errno = 0; EXPECT_EQ(0U, fwrite("hello", 1, 2, fp)); EXPECT_EQ(EBADF, errno); errno = 0; EXPECT_EQ(EOF, fputs("hello", fp)); EXPECT_EQ(EBADF, errno); errno = 0; EXPECT_EQ(WEOF, fputwc(L'x', fp)); #if defined(__BIONIC__) EXPECT_EQ(EBADF, errno); #endif } // Tests that we can only have a consistent and correct fpos_t when using // f*pos functions (i.e. fpos doesn't get inside a multi byte character). TEST(STDIO_TEST, consistent_fpos_t) { ASSERT_STREQ("C.UTF-8", setlocale(LC_CTYPE, "C.UTF-8")); uselocale(LC_GLOBAL_LOCALE); FILE* fp = tmpfile(); ASSERT_TRUE(fp != nullptr); wchar_t mb_one_bytes = L'h'; wchar_t mb_two_bytes = 0x00a2; wchar_t mb_three_bytes = 0x20ac; wchar_t mb_four_bytes = 0x24b62; // Write to file. ASSERT_EQ(mb_one_bytes, static_cast<wchar_t>(fputwc(mb_one_bytes, fp))); ASSERT_EQ(mb_two_bytes, static_cast<wchar_t>(fputwc(mb_two_bytes, fp))); ASSERT_EQ(mb_three_bytes, static_cast<wchar_t>(fputwc(mb_three_bytes, fp))); ASSERT_EQ(mb_four_bytes, static_cast<wchar_t>(fputwc(mb_four_bytes, fp))); rewind(fp); // Record each character position. fpos_t pos1; fpos_t pos2; fpos_t pos3; fpos_t pos4; fpos_t pos5; EXPECT_EQ(0, fgetpos(fp, &pos1)); ASSERT_EQ(mb_one_bytes, static_cast<wchar_t>(fgetwc(fp))); EXPECT_EQ(0, fgetpos(fp, &pos2)); ASSERT_EQ(mb_two_bytes, static_cast<wchar_t>(fgetwc(fp))); EXPECT_EQ(0, fgetpos(fp, &pos3)); ASSERT_EQ(mb_three_bytes, static_cast<wchar_t>(fgetwc(fp))); EXPECT_EQ(0, fgetpos(fp, &pos4)); ASSERT_EQ(mb_four_bytes, static_cast<wchar_t>(fgetwc(fp))); EXPECT_EQ(0, fgetpos(fp, &pos5)); #if defined(__BIONIC__) // Bionic's fpos_t is just an alias for off_t. This is inherited from OpenBSD // upstream. Glibc differs by storing the mbstate_t inside its fpos_t. In // Bionic (and upstream OpenBSD) the mbstate_t is stored inside the FILE // structure. ASSERT_EQ(0, static_cast<off_t>(pos1)); ASSERT_EQ(1, static_cast<off_t>(pos2)); ASSERT_EQ(3, static_cast<off_t>(pos3)); ASSERT_EQ(6, static_cast<off_t>(pos4)); ASSERT_EQ(10, static_cast<off_t>(pos5)); #endif // Exercise back and forth movements of the position. ASSERT_EQ(0, fsetpos(fp, &pos2)); ASSERT_EQ(mb_two_bytes, static_cast<wchar_t>(fgetwc(fp))); ASSERT_EQ(0, fsetpos(fp, &pos1)); ASSERT_EQ(mb_one_bytes, static_cast<wchar_t>(fgetwc(fp))); ASSERT_EQ(0, fsetpos(fp, &pos4)); ASSERT_EQ(mb_four_bytes, static_cast<wchar_t>(fgetwc(fp))); ASSERT_EQ(0, fsetpos(fp, &pos3)); ASSERT_EQ(mb_three_bytes, static_cast<wchar_t>(fgetwc(fp))); ASSERT_EQ(0, fsetpos(fp, &pos5)); ASSERT_EQ(WEOF, fgetwc(fp)); fclose(fp); } // Exercise the interaction between fpos and seek. TEST(STDIO_TEST, fpos_t_and_seek) { ASSERT_STREQ("C.UTF-8", setlocale(LC_CTYPE, "C.UTF-8")); uselocale(LC_GLOBAL_LOCALE); // In glibc-2.16 fseek doesn't work properly in wide mode // (https://sourceware.org/bugzilla/show_bug.cgi?id=14543). One workaround is // to close and re-open the file. We do it in order to make the test pass // with all glibcs. TemporaryFile tf; FILE* fp = fdopen(tf.fd, "w+"); ASSERT_TRUE(fp != nullptr); wchar_t mb_two_bytes = 0x00a2; wchar_t mb_three_bytes = 0x20ac; wchar_t mb_four_bytes = 0x24b62; // Write to file. ASSERT_EQ(mb_two_bytes, static_cast<wchar_t>(fputwc(mb_two_bytes, fp))); ASSERT_EQ(mb_three_bytes, static_cast<wchar_t>(fputwc(mb_three_bytes, fp))); ASSERT_EQ(mb_four_bytes, static_cast<wchar_t>(fputwc(mb_four_bytes, fp))); fflush(fp); fclose(fp); fp = fopen(tf.path, "r"); ASSERT_TRUE(fp != nullptr); // Store a valid position. fpos_t mb_two_bytes_pos; ASSERT_EQ(0, fgetpos(fp, &mb_two_bytes_pos)); // Move inside mb_four_bytes with fseek. long offset_inside_mb = 6; ASSERT_EQ(0, fseek(fp, offset_inside_mb, SEEK_SET)); // Store the "inside multi byte" position. fpos_t pos_inside_mb; ASSERT_EQ(0, fgetpos(fp, &pos_inside_mb)); #if defined(__BIONIC__) ASSERT_EQ(offset_inside_mb, static_cast<off_t>(pos_inside_mb)); #endif // Reading from within a byte should produce an error. ASSERT_EQ(WEOF, fgetwc(fp)); ASSERT_EQ(EILSEQ, errno); // Reverting to a valid position should work. ASSERT_EQ(0, fsetpos(fp, &mb_two_bytes_pos)); ASSERT_EQ(mb_two_bytes, static_cast<wchar_t>(fgetwc(fp))); // Moving withing a multi byte with fsetpos should work but reading should // produce an error. ASSERT_EQ(0, fsetpos(fp, &pos_inside_mb)); ASSERT_EQ(WEOF, fgetwc(fp)); ASSERT_EQ(EILSEQ, errno); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen) { char buf[16]; memset(buf, 0, sizeof(buf)); FILE* fp = fmemopen(buf, sizeof(buf), "r+"); ASSERT_EQ('<', fputc('<', fp)); ASSERT_NE(EOF, fputs("abc>\n", fp)); fflush(fp); // We wrote to the buffer... ASSERT_STREQ("<abc>\n", buf); // And can read back from the file. AssertFileIs(fp, "<abc>\n", true); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_nullptr) { FILE* fp = fmemopen(nullptr, 128, "r+"); ASSERT_NE(EOF, fputs("xyz\n", fp)); AssertFileIs(fp, "xyz\n", true); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_trailing_NUL_byte) { FILE* fp; char buf[8]; // POSIX: "When a stream open for writing is flushed or closed, a null byte // shall be written at the current position or at the end of the buffer, // depending on the size of the contents." memset(buf, 'x', sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "w")); // Even with nothing written (and not in truncate mode), we'll flush a NUL... ASSERT_EQ(0, fflush(fp)); EXPECT_EQ("\0xxxxxxx"s, std::string(buf, buf + sizeof(buf))); // Now write and check that the NUL moves along with our writes... ASSERT_NE(EOF, fputs("hello", fp)); ASSERT_EQ(0, fflush(fp)); EXPECT_EQ("hello\0xx"s, std::string(buf, buf + sizeof(buf))); ASSERT_NE(EOF, fputs("wo", fp)); ASSERT_EQ(0, fflush(fp)); EXPECT_EQ("hellowo\0"s, std::string(buf, buf + sizeof(buf))); ASSERT_EQ(0, fclose(fp)); // "If a stream open for update is flushed or closed and the last write has // advanced the current buffer size, a null byte shall be written at the end // of the buffer if it fits." memset(buf, 'x', sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "r+")); // Nothing written yet, so no advance... ASSERT_EQ(0, fflush(fp)); EXPECT_EQ("xxxxxxxx"s, std::string(buf, buf + sizeof(buf))); ASSERT_NE(EOF, fputs("hello", fp)); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_size) { FILE* fp; char buf[16]; memset(buf, 'x', sizeof(buf)); // POSIX: "The stream shall also maintain the size of the current buffer // contents; use of fseek() or fseeko() on the stream with SEEK_END shall // seek relative to this size." // "For modes r and r+ the size shall be set to the value given by the size // argument." ASSERT_NE(nullptr, fp = fmemopen(buf, 16, "r")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(buf, 16, "r+")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fclose(fp)); // "For modes w and w+ the initial size shall be zero..." ASSERT_NE(nullptr, fp = fmemopen(nullptr, 16, "w")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(nullptr, 16, "w+")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fclose(fp)); // "...and for modes a and a+ the initial size shall be: // 1. Zero, if buf is a null pointer ASSERT_NE(nullptr, fp = fmemopen(nullptr, 16, "a")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(nullptr, 16, "a+")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); EXPECT_EQ(0, ftello(fp)); ASSERT_EQ(0, fclose(fp)); // 2. The position of the first null byte in the buffer, if one is found memset(buf, 'x', sizeof(buf)); buf[3] = '\0'; ASSERT_NE(nullptr, fp = fmemopen(buf, 16, "a")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(3, ftell(fp)); EXPECT_EQ(3, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(3, ftell(fp)); EXPECT_EQ(3, ftello(fp)); ASSERT_EQ(0, fclose(fp)); memset(buf, 'x', sizeof(buf)); buf[3] = '\0'; ASSERT_NE(nullptr, fp = fmemopen(buf, 16, "a+")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(3, ftell(fp)); EXPECT_EQ(3, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(3, ftell(fp)); EXPECT_EQ(3, ftello(fp)); ASSERT_EQ(0, fclose(fp)); // 3. The value of the size argument, if buf is not a null pointer and no // null byte is found. memset(buf, 'x', sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, 16, "a")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fclose(fp)); memset(buf, 'x', sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, 16, "a+")); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fseeko(fp, 0, SEEK_END)); EXPECT_EQ(16, ftell(fp)); EXPECT_EQ(16, ftello(fp)); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_SEEK_END) { // fseek SEEK_END is relative to the current string length, not the buffer size. FILE* fp; char buf[8]; memset(buf, 'x', sizeof(buf)); strcpy(buf, "str"); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "w+")); ASSERT_NE(EOF, fputs("string", fp)); EXPECT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(static_cast<long>(strlen("string")), ftell(fp)); EXPECT_EQ(static_cast<off_t>(strlen("string")), ftello(fp)); EXPECT_EQ(0, fclose(fp)); // glibc < 2.22 interpreted SEEK_END the wrong way round (subtracting rather // than adding). ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "w+")); ASSERT_NE(EOF, fputs("54321", fp)); EXPECT_EQ(0, fseek(fp, -2, SEEK_END)); EXPECT_EQ('2', fgetc(fp)); EXPECT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_seek_invalid) { char buf[8]; memset(buf, 'x', sizeof(buf)); FILE* fp = fmemopen(buf, sizeof(buf), "w"); ASSERT_TRUE(fp != nullptr); // POSIX: "An attempt to seek ... to a negative position or to a position // larger than the buffer size given in the size argument shall fail." // (There's no mention of what errno should be set to, and glibc doesn't // set errno in any of these cases.) EXPECT_EQ(-1, fseek(fp, -2, SEEK_SET)); EXPECT_EQ(-1, fseeko(fp, -2, SEEK_SET)); EXPECT_EQ(-1, fseek(fp, sizeof(buf) + 1, SEEK_SET)); EXPECT_EQ(-1, fseeko(fp, sizeof(buf) + 1, SEEK_SET)); } TEST(STDIO_TEST, fmemopen_read_EOF) { // POSIX: "A read operation on the stream shall not advance the current // buffer position beyond the current buffer size." char buf[8]; memset(buf, 'x', sizeof(buf)); FILE* fp = fmemopen(buf, sizeof(buf), "r"); ASSERT_TRUE(fp != nullptr); char buf2[BUFSIZ]; ASSERT_EQ(8U, fread(buf2, 1, sizeof(buf2), fp)); // POSIX: "Reaching the buffer size in a read operation shall count as // end-of-file. ASSERT_TRUE(feof(fp)); ASSERT_EQ(EOF, fgetc(fp)); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_read_null_bytes) { // POSIX: "Null bytes in the buffer shall have no special meaning for reads." char buf[] = "h\0e\0l\0l\0o"; FILE* fp = fmemopen(buf, sizeof(buf), "r"); ASSERT_TRUE(fp != nullptr); ASSERT_EQ('h', fgetc(fp)); ASSERT_EQ(0, fgetc(fp)); ASSERT_EQ('e', fgetc(fp)); ASSERT_EQ(0, fgetc(fp)); ASSERT_EQ('l', fgetc(fp)); ASSERT_EQ(0, fgetc(fp)); // POSIX: "The read operation shall start at the current buffer position of // the stream." char buf2[8]; memset(buf2, 'x', sizeof(buf2)); ASSERT_EQ(4U, fread(buf2, 1, sizeof(buf2), fp)); ASSERT_EQ('l', buf2[0]); ASSERT_EQ(0, buf2[1]); ASSERT_EQ('o', buf2[2]); ASSERT_EQ(0, buf2[3]); for (size_t i = 4; i < sizeof(buf2); ++i) ASSERT_EQ('x', buf2[i]) << i; ASSERT_TRUE(feof(fp)); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_write) { FILE* fp; char buf[8]; // POSIX: "A write operation shall start either at the current position of // the stream (if mode has not specified 'a' as the first character)..." memset(buf, 'x', sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "r+")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(0, fseek(fp, 2, SEEK_SET)); ASSERT_EQ(' ', fputc(' ', fp)); EXPECT_EQ("xx xxxxx", std::string(buf, buf + sizeof(buf))); ASSERT_EQ(0, fclose(fp)); // "...or at the current size of the stream (if mode had 'a' as the first // character)." (See the fmemopen_size test for what "size" means, but for // mode "a", it's the first NUL byte.) memset(buf, 'x', sizeof(buf)); buf[3] = '\0'; ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "a+")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(' ', fputc(' ', fp)); EXPECT_EQ("xxx \0xxx"s, std::string(buf, buf + sizeof(buf))); ASSERT_EQ(0, fclose(fp)); // "If the current position at the end of the write is larger than the // current buffer size, the current buffer size shall be set to the current // position." (See the fmemopen_size test for what "size" means, but to // query it we SEEK_END with offset 0, and then ftell.) memset(buf, 'x', sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "w+")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(0, ftell(fp)); ASSERT_EQ(' ', fputc(' ', fp)); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(1, ftell(fp)); ASSERT_NE(EOF, fputs("123", fp)); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(4, ftell(fp)); EXPECT_EQ(" 123\0xxx"s, std::string(buf, buf + sizeof(buf))); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_write_EOF) { // POSIX: "A write operation on the stream shall not advance the current // buffer size beyond the size given in the size argument." FILE* fp; // Scalar writes... ASSERT_NE(nullptr, fp = fmemopen(nullptr, 4, "w")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ('x', fputc('x', fp)); ASSERT_EQ('x', fputc('x', fp)); ASSERT_EQ('x', fputc('x', fp)); ASSERT_EQ(EOF, fputc('x', fp)); // Only 3 fit because of the implicit NUL. ASSERT_EQ(0, fclose(fp)); // Vector writes... ASSERT_NE(nullptr, fp = fmemopen(nullptr, 4, "w")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(3U, fwrite("xxxx", 1, 4, fp)); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_initial_position) { // POSIX: "The ... current position in the buffer ... shall be initially // set to either the beginning of the buffer (for r and w modes) ..." char buf[] = "hello\0world"; FILE* fp; ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "r")); EXPECT_EQ(0L, ftell(fp)); EXPECT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "w")); EXPECT_EQ(0L, ftell(fp)); EXPECT_EQ(0, fclose(fp)); buf[0] = 'h'; // (Undo the effects of the above.) // POSIX: "...or to the first null byte in the buffer (for a modes)." ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "a")); EXPECT_EQ(5L, ftell(fp)); EXPECT_EQ(0, fclose(fp)); // POSIX: "If no null byte is found in append mode, the initial position // shall be set to one byte after the end of the buffer." memset(buf, 'x', sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "a")); EXPECT_EQ(static_cast<long>(sizeof(buf)), ftell(fp)); EXPECT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_initial_position_allocated) { // POSIX: "If buf is a null pointer, the initial position shall always be // set to the beginning of the buffer." FILE* fp = fmemopen(nullptr, 128, "a+"); ASSERT_TRUE(fp != nullptr); EXPECT_EQ(0L, ftell(fp)); EXPECT_EQ(0L, fseek(fp, 0, SEEK_SET)); EXPECT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_zero_length) { // POSIX says it's up to the implementation whether or not you can have a // zero-length buffer (but "A future version of this standard may require // support of zero-length buffer streams explicitly"). BSD and glibc < 2.22 // agreed that you couldn't, but glibc >= 2.22 allows it for consistency. FILE* fp; char buf[16]; ASSERT_NE(nullptr, fp = fmemopen(buf, 0, "r+")); ASSERT_EQ(EOF, fgetc(fp)); ASSERT_TRUE(feof(fp)); ASSERT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(nullptr, 0, "r+")); ASSERT_EQ(EOF, fgetc(fp)); ASSERT_TRUE(feof(fp)); ASSERT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(buf, 0, "w+")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(EOF, fputc('x', fp)); ASSERT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(nullptr, 0, "w+")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(EOF, fputc('x', fp)); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_zero_length_buffer_overrun) { char buf[2] = "x"; ASSERT_EQ('x', buf[0]); FILE* fp = fmemopen(buf, 0, "w"); ASSERT_EQ('x', buf[0]); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_write_only_allocated) { // POSIX says fmemopen "may fail if the mode argument does not include a '+'". // BSD fails, glibc doesn't. We side with the more lenient. FILE* fp; ASSERT_NE(nullptr, fp = fmemopen(nullptr, 16, "r")); ASSERT_EQ(0, fclose(fp)); ASSERT_NE(nullptr, fp = fmemopen(nullptr, 16, "w")); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_fileno) { // There's no fd backing an fmemopen FILE*. FILE* fp = fmemopen(nullptr, 16, "r"); ASSERT_TRUE(fp != nullptr); errno = 0; ASSERT_EQ(-1, fileno(fp)); ASSERT_EQ(EBADF, errno); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fmemopen_append_after_seek) { // In BSD and glibc < 2.22, append mode didn't force writes to append if // there had been an intervening seek. FILE* fp; char buf[] = "hello\0world"; ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "a")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(0, fseek(fp, 0, SEEK_SET)); ASSERT_NE(EOF, fputc('!', fp)); EXPECT_EQ("hello!\0orld\0"s, std::string(buf, buf + sizeof(buf))); ASSERT_EQ(0, fclose(fp)); memcpy(buf, "hello\0world", sizeof(buf)); ASSERT_NE(nullptr, fp = fmemopen(buf, sizeof(buf), "a+")); setbuf(fp, nullptr); // Turn off buffering so we can see what's happening as it happens. ASSERT_EQ(0, fseek(fp, 0, SEEK_SET)); ASSERT_NE(EOF, fputc('!', fp)); EXPECT_EQ("hello!\0orld\0"s, std::string(buf, buf + sizeof(buf))); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, open_memstream) { char* p = nullptr; size_t size = 0; FILE* fp = open_memstream(&p, &size); ASSERT_NE(EOF, fputs("hello, world!", fp)); fclose(fp); ASSERT_STREQ("hello, world!", p); ASSERT_EQ(strlen("hello, world!"), size); free(p); } TEST(STDIO_TEST, open_memstream_EINVAL) { #if defined(__BIONIC__) char* p; size_t size; // Invalid buffer. errno = 0; ASSERT_EQ(nullptr, open_memstream(nullptr, &size)); ASSERT_EQ(EINVAL, errno); // Invalid size. errno = 0; ASSERT_EQ(nullptr, open_memstream(&p, nullptr)); ASSERT_EQ(EINVAL, errno); #else GTEST_SKIP() << "glibc is broken"; #endif } TEST(STDIO_TEST, fdopen_CLOEXEC) { int fd = open("/proc/version", O_RDONLY); ASSERT_TRUE(fd != -1); // This fd doesn't have O_CLOEXEC... AssertCloseOnExec(fd, false); FILE* fp = fdopen(fd, "re"); ASSERT_TRUE(fp != nullptr); // ...but the new one does. AssertCloseOnExec(fileno(fp), true); fclose(fp); } TEST(STDIO_TEST, freopen_CLOEXEC) { FILE* fp = fopen("/proc/version", "r"); ASSERT_TRUE(fp != nullptr); // This FILE* doesn't have O_CLOEXEC... AssertCloseOnExec(fileno(fp), false); fp = freopen("/proc/version", "re", fp); // ...but the new one does. AssertCloseOnExec(fileno(fp), true); fclose(fp); } TEST(STDIO_TEST, fopen64_freopen64) { FILE* fp = fopen64("/proc/version", "r"); ASSERT_TRUE(fp != nullptr); fp = freopen64("/proc/version", "re", fp); ASSERT_TRUE(fp != nullptr); fclose(fp); } // https://code.google.com/p/android/issues/detail?id=81155 // http://b/18556607 TEST(STDIO_TEST, fread_unbuffered_pathological_performance) { FILE* fp = fopen("/dev/zero", "r"); ASSERT_TRUE(fp != nullptr); // Make this stream unbuffered. setvbuf(fp, nullptr, _IONBF, 0); char buf[65*1024]; memset(buf, 0xff, sizeof(buf)); time_t t0 = time(nullptr); for (size_t i = 0; i < 1024; ++i) { ASSERT_EQ(1U, fread(buf, 64*1024, 1, fp)); } time_t t1 = time(nullptr); fclose(fp); // 1024 64KiB reads should have been very quick. ASSERT_LE(t1 - t0, 1); for (size_t i = 0; i < 64*1024; ++i) { ASSERT_EQ('\0', buf[i]); } for (size_t i = 64*1024; i < 65*1024; ++i) { ASSERT_EQ('\xff', buf[i]); } } TEST(STDIO_TEST, fread_EOF) { std::string digits("0123456789"); FILE* fp = fmemopen(&digits[0], digits.size(), "r"); // Try to read too much, but little enough that it still fits in the FILE's internal buffer. char buf1[4 * 4]; memset(buf1, 0, sizeof(buf1)); ASSERT_EQ(2U, fread(buf1, 4, 4, fp)); ASSERT_STREQ("0123456789", buf1); ASSERT_TRUE(feof(fp)); rewind(fp); // Try to read way too much so stdio tries to read more direct from the stream. char buf2[4 * 4096]; memset(buf2, 0, sizeof(buf2)); ASSERT_EQ(2U, fread(buf2, 4, 4096, fp)); ASSERT_STREQ("0123456789", buf2); ASSERT_TRUE(feof(fp)); fclose(fp); } static void test_fread_from_write_only_stream(size_t n) { FILE* fp = fopen("/dev/null", "w"); std::vector<char> buf(n, 0); errno = 0; ASSERT_EQ(0U, fread(&buf[0], n, 1, fp)); ASSERT_EQ(EBADF, errno); ASSERT_TRUE(ferror(fp)); ASSERT_FALSE(feof(fp)); fclose(fp); } TEST(STDIO_TEST, fread_from_write_only_stream_slow_path) { test_fread_from_write_only_stream(1); } TEST(STDIO_TEST, fread_from_write_only_stream_fast_path) { test_fread_from_write_only_stream(64*1024); } static void test_fwrite_after_fread(size_t n) { TemporaryFile tf; FILE* fp = fdopen(tf.fd, "w+"); ASSERT_EQ(1U, fwrite("1", 1, 1, fp)); fflush(fp); // We've flushed but not rewound, so there's nothing to read. std::vector<char> buf(n, 0); ASSERT_EQ(0U, fread(&buf[0], 1, buf.size(), fp)); ASSERT_TRUE(feof(fp)); // But hitting EOF doesn't prevent us from writing... errno = 0; ASSERT_EQ(1U, fwrite("2", 1, 1, fp)) << strerror(errno); // And if we rewind, everything's there. rewind(fp); ASSERT_EQ(2U, fread(&buf[0], 1, buf.size(), fp)); ASSERT_EQ('1', buf[0]); ASSERT_EQ('2', buf[1]); fclose(fp); } TEST(STDIO_TEST, fwrite_after_fread_slow_path) { test_fwrite_after_fread(16); } TEST(STDIO_TEST, fwrite_after_fread_fast_path) { test_fwrite_after_fread(64*1024); } // http://b/19172514 TEST(STDIO_TEST, fread_after_fseek) { TemporaryFile tf; FILE* fp = fopen(tf.path, "w+"); ASSERT_TRUE(fp != nullptr); char file_data[12288]; for (size_t i = 0; i < 12288; i++) { file_data[i] = i; } ASSERT_EQ(12288U, fwrite(file_data, 1, 12288, fp)); fclose(fp); fp = fopen(tf.path, "r"); ASSERT_TRUE(fp != nullptr); char buffer[8192]; size_t cur_location = 0; // Small read to populate internal buffer. ASSERT_EQ(100U, fread(buffer, 1, 100, fp)); ASSERT_EQ(memcmp(file_data, buffer, 100), 0); cur_location = static_cast<size_t>(ftell(fp)); // Large read to force reading into the user supplied buffer and bypassing // the internal buffer. ASSERT_EQ(8192U, fread(buffer, 1, 8192, fp)); ASSERT_EQ(memcmp(file_data+cur_location, buffer, 8192), 0); // Small backwards seek to verify fseek does not reuse the internal buffer. ASSERT_EQ(0, fseek(fp, -22, SEEK_CUR)) << strerror(errno); cur_location = static_cast<size_t>(ftell(fp)); ASSERT_EQ(22U, fread(buffer, 1, 22, fp)); ASSERT_EQ(memcmp(file_data+cur_location, buffer, 22), 0); fclose(fp); } // https://code.google.com/p/android/issues/detail?id=184847 TEST(STDIO_TEST, fread_EOF_184847) { TemporaryFile tf; char buf[6] = {0}; FILE* fw = fopen(tf.path, "w"); ASSERT_TRUE(fw != nullptr); FILE* fr = fopen(tf.path, "r"); ASSERT_TRUE(fr != nullptr); fwrite("a", 1, 1, fw); fflush(fw); ASSERT_EQ(1U, fread(buf, 1, 1, fr)); ASSERT_STREQ("a", buf); // 'fr' is now at EOF. ASSERT_EQ(0U, fread(buf, 1, 1, fr)); ASSERT_TRUE(feof(fr)); // Write some more... fwrite("z", 1, 1, fw); fflush(fw); // ...and check that we can read it back. // (BSD thinks that once a stream has hit EOF, it must always return EOF. SysV disagrees.) ASSERT_EQ(1U, fread(buf, 1, 1, fr)); ASSERT_STREQ("z", buf); // But now we're done. ASSERT_EQ(0U, fread(buf, 1, 1, fr)); fclose(fr); fclose(fw); } TEST(STDIO_TEST, fclose_invalidates_fd) { // The typical error we're trying to help people catch involves accessing // memory after it's been freed. But we know that stdin/stdout/stderr are // special and don't get deallocated, so this test uses stdin. ASSERT_EQ(0, fclose(stdin)); // Even though using a FILE* after close is undefined behavior, I've closed // this bug as "WAI" too many times. We shouldn't hand out stale fds, // especially because they might actually correspond to a real stream. errno = 0; ASSERT_EQ(-1, fileno(stdin)); ASSERT_EQ(EBADF, errno); } TEST(STDIO_TEST, fseek_ftell_unseekable) { #if defined(__BIONIC__) // glibc has fopencookie instead. auto read_fn = [](void*, char*, int) { return -1; }; FILE* fp = funopen(nullptr, read_fn, nullptr, nullptr, nullptr); ASSERT_TRUE(fp != nullptr); // Check that ftell balks on an unseekable FILE*. errno = 0; ASSERT_EQ(-1, ftell(fp)); ASSERT_EQ(ESPIPE, errno); // SEEK_CUR is rewritten as SEEK_SET internally... errno = 0; ASSERT_EQ(-1, fseek(fp, 0, SEEK_CUR)); ASSERT_EQ(ESPIPE, errno); // ...so it's worth testing the direct seek path too. errno = 0; ASSERT_EQ(-1, fseek(fp, 0, SEEK_SET)); ASSERT_EQ(ESPIPE, errno); fclose(fp); #else GTEST_SKIP() << "glibc uses fopencookie instead"; #endif } TEST(STDIO_TEST, funopen_EINVAL) { #if defined(__BIONIC__) errno = 0; ASSERT_EQ(nullptr, funopen(nullptr, nullptr, nullptr, nullptr, nullptr)); ASSERT_EQ(EINVAL, errno); #else GTEST_SKIP() << "glibc uses fopencookie instead"; #endif } TEST(STDIO_TEST, funopen_seek) { #if defined(__BIONIC__) auto read_fn = [](void*, char*, int) { return -1; }; auto seek_fn = [](void*, fpos_t, int) -> fpos_t { return 0xfedcba12; }; auto seek64_fn = [](void*, fpos64_t, int) -> fpos64_t { return 0xfedcba12345678; }; FILE* fp = funopen(nullptr, read_fn, nullptr, seek_fn, nullptr); ASSERT_TRUE(fp != nullptr); fpos_t pos; #if defined(__LP64__) EXPECT_EQ(0, fgetpos(fp, &pos)) << strerror(errno); EXPECT_EQ(0xfedcba12LL, pos); #else EXPECT_EQ(-1, fgetpos(fp, &pos)) << strerror(errno); EXPECT_EQ(EOVERFLOW, errno); #endif FILE* fp64 = funopen64(nullptr, read_fn, nullptr, seek64_fn, nullptr); ASSERT_TRUE(fp64 != nullptr); fpos64_t pos64; EXPECT_EQ(0, fgetpos64(fp64, &pos64)) << strerror(errno); EXPECT_EQ(0xfedcba12345678, pos64); #else GTEST_SKIP() << "glibc uses fopencookie instead"; #endif } TEST(STDIO_TEST, lots_of_concurrent_files) { std::vector<TemporaryFile*> tfs; std::vector<FILE*> fps; for (size_t i = 0; i < 256; ++i) { TemporaryFile* tf = new TemporaryFile; tfs.push_back(tf); FILE* fp = fopen(tf->path, "w+"); fps.push_back(fp); fprintf(fp, "hello %zu!\n", i); fflush(fp); } for (size_t i = 0; i < 256; ++i) { char expected[BUFSIZ]; snprintf(expected, sizeof(expected), "hello %zu!\n", i); AssertFileIs(fps[i], expected); fclose(fps[i]); delete tfs[i]; } } static void AssertFileOffsetAt(FILE* fp, off64_t offset) { EXPECT_EQ(offset, ftell(fp)); EXPECT_EQ(offset, ftello(fp)); EXPECT_EQ(offset, ftello64(fp)); fpos_t pos; fpos64_t pos64; EXPECT_EQ(0, fgetpos(fp, &pos)); EXPECT_EQ(0, fgetpos64(fp, &pos64)); #if defined(__BIONIC__) EXPECT_EQ(offset, static_cast<off64_t>(pos)); EXPECT_EQ(offset, static_cast<off64_t>(pos64)); #else GTEST_SKIP() << "glibc's fpos_t is opaque"; #endif } TEST(STDIO_TEST, seek_tell_family_smoke) { TemporaryFile tf; FILE* fp = fdopen(tf.fd, "w+"); // Initially we should be at 0. AssertFileOffsetAt(fp, 0); // Seek to offset 8192. ASSERT_EQ(0, fseek(fp, 8192, SEEK_SET)); AssertFileOffsetAt(fp, 8192); fpos_t eight_k_pos; ASSERT_EQ(0, fgetpos(fp, &eight_k_pos)); // Seek forward another 8192... ASSERT_EQ(0, fseek(fp, 8192, SEEK_CUR)); AssertFileOffsetAt(fp, 8192 + 8192); fpos64_t sixteen_k_pos64; ASSERT_EQ(0, fgetpos64(fp, &sixteen_k_pos64)); // Seek back 8192... ASSERT_EQ(0, fseek(fp, -8192, SEEK_CUR)); AssertFileOffsetAt(fp, 8192); // Since we haven't written anything, the end is also at 0. ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); AssertFileOffsetAt(fp, 0); // Check that our fpos64_t from 16KiB works... ASSERT_EQ(0, fsetpos64(fp, &sixteen_k_pos64)); AssertFileOffsetAt(fp, 8192 + 8192); // ...as does our fpos_t from 8192. ASSERT_EQ(0, fsetpos(fp, &eight_k_pos)); AssertFileOffsetAt(fp, 8192); // Do fseeko and fseeko64 work too? ASSERT_EQ(0, fseeko(fp, 1234, SEEK_SET)); AssertFileOffsetAt(fp, 1234); ASSERT_EQ(0, fseeko64(fp, 5678, SEEK_SET)); AssertFileOffsetAt(fp, 5678); fclose(fp); } TEST(STDIO_TEST, fseek_fseeko_EINVAL) { TemporaryFile tf; FILE* fp = fdopen(tf.fd, "w+"); // Bad whence. errno = 0; ASSERT_EQ(-1, fseek(fp, 0, 123)); ASSERT_EQ(EINVAL, errno); errno = 0; ASSERT_EQ(-1, fseeko(fp, 0, 123)); ASSERT_EQ(EINVAL, errno); errno = 0; ASSERT_EQ(-1, fseeko64(fp, 0, 123)); ASSERT_EQ(EINVAL, errno); // Bad offset. errno = 0; ASSERT_EQ(-1, fseek(fp, -1, SEEK_SET)); ASSERT_EQ(EINVAL, errno); errno = 0; ASSERT_EQ(-1, fseeko(fp, -1, SEEK_SET)); ASSERT_EQ(EINVAL, errno); errno = 0; ASSERT_EQ(-1, fseeko64(fp, -1, SEEK_SET)); ASSERT_EQ(EINVAL, errno); fclose(fp); } TEST(STDIO_TEST, ctermid) { ASSERT_STREQ("/dev/tty", ctermid(nullptr)); char buf[L_ctermid] = {}; ASSERT_EQ(buf, ctermid(buf)); ASSERT_STREQ("/dev/tty", buf); } TEST(STDIO_TEST, remove) { struct stat sb; TemporaryFile tf; ASSERT_EQ(0, remove(tf.path)); ASSERT_EQ(-1, lstat(tf.path, &sb)); ASSERT_EQ(ENOENT, errno); TemporaryDir td; ASSERT_EQ(0, remove(td.path)); ASSERT_EQ(-1, lstat(td.path, &sb)); ASSERT_EQ(ENOENT, errno); errno = 0; ASSERT_EQ(-1, remove(tf.path)); ASSERT_EQ(ENOENT, errno); errno = 0; ASSERT_EQ(-1, remove(td.path)); ASSERT_EQ(ENOENT, errno); } TEST(STDIO_DEATHTEST, snprintf_30445072_known_buffer_size) { char buf[16]; ASSERT_EXIT(snprintf(buf, atol("-1"), "hello"), testing::KilledBySignal(SIGABRT), #if defined(NOFORTIFY) "FORTIFY: vsnprintf: size .* > SSIZE_MAX" #else "FORTIFY: vsnprintf: prevented .*-byte write into 16-byte buffer" #endif ); } TEST(STDIO_DEATHTEST, snprintf_30445072_unknown_buffer_size) { std::string buf = "world"; ASSERT_EXIT(snprintf(&buf[0], atol("-1"), "hello"), testing::KilledBySignal(SIGABRT), "FORTIFY: vsnprintf: size .* > SSIZE_MAX"); } TEST(STDIO_TEST, sprintf_30445072) { std::string buf = "world"; sprintf(&buf[0], "hello"); ASSERT_EQ(buf, "hello"); } TEST(STDIO_TEST, printf_m) { char buf[BUFSIZ]; errno = 0; snprintf(buf, sizeof(buf), "<%m>"); ASSERT_STREQ("<Success>", buf); errno = -1; snprintf(buf, sizeof(buf), "<%m>"); ASSERT_STREQ("<Unknown error -1>", buf); errno = EINVAL; snprintf(buf, sizeof(buf), "<%m>"); ASSERT_STREQ("<Invalid argument>", buf); } TEST(STDIO_TEST, printf_m_does_not_clobber_strerror) { char buf[BUFSIZ]; const char* m = strerror(-1); ASSERT_STREQ("Unknown error -1", m); errno = -2; snprintf(buf, sizeof(buf), "<%m>"); ASSERT_STREQ("<Unknown error -2>", buf); ASSERT_STREQ("Unknown error -1", m); } TEST(STDIO_TEST, wprintf_m) { wchar_t buf[BUFSIZ]; errno = 0; swprintf(buf, sizeof(buf), L"<%m>"); ASSERT_EQ(std::wstring(L"<Success>"), buf); errno = -1; swprintf(buf, sizeof(buf), L"<%m>"); ASSERT_EQ(std::wstring(L"<Unknown error -1>"), buf); errno = EINVAL; swprintf(buf, sizeof(buf), L"<%m>"); ASSERT_EQ(std::wstring(L"<Invalid argument>"), buf); } TEST(STDIO_TEST, wprintf_m_does_not_clobber_strerror) { wchar_t buf[BUFSIZ]; const char* m = strerror(-1); ASSERT_STREQ("Unknown error -1", m); errno = -2; swprintf(buf, sizeof(buf), L"<%m>"); ASSERT_EQ(std::wstring(L"<Unknown error -2>"), buf); ASSERT_STREQ("Unknown error -1", m); } TEST(STDIO_TEST, fopen_append_mode_and_ftell) { TemporaryFile tf; SetFileTo(tf.path, "0123456789"); FILE* fp = fopen(tf.path, "a"); EXPECT_EQ(10, ftell(fp)); ASSERT_EQ(0, fseek(fp, 2, SEEK_SET)); EXPECT_EQ(2, ftell(fp)); ASSERT_NE(EOF, fputs("xxx", fp)); ASSERT_EQ(0, fflush(fp)); EXPECT_EQ(13, ftell(fp)); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(13, ftell(fp)); ASSERT_EQ(0, fclose(fp)); AssertFileIs(tf.path, "0123456789xxx"); } TEST(STDIO_TEST, fdopen_append_mode_and_ftell) { TemporaryFile tf; SetFileTo(tf.path, "0123456789"); int fd = open(tf.path, O_RDWR); ASSERT_NE(-1, fd); // POSIX: "The file position indicator associated with the new stream is set to the position // indicated by the file offset associated with the file descriptor." ASSERT_EQ(4, lseek(fd, 4, SEEK_SET)); FILE* fp = fdopen(fd, "a"); EXPECT_EQ(4, ftell(fp)); ASSERT_EQ(0, fseek(fp, 2, SEEK_SET)); EXPECT_EQ(2, ftell(fp)); ASSERT_NE(EOF, fputs("xxx", fp)); ASSERT_EQ(0, fflush(fp)); EXPECT_EQ(13, ftell(fp)); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(13, ftell(fp)); ASSERT_EQ(0, fclose(fp)); AssertFileIs(tf.path, "0123456789xxx"); } TEST(STDIO_TEST, freopen_append_mode_and_ftell) { TemporaryFile tf; SetFileTo(tf.path, "0123456789"); FILE* other_fp = fopen("/proc/version", "r"); FILE* fp = freopen(tf.path, "a", other_fp); EXPECT_EQ(10, ftell(fp)); ASSERT_EQ(0, fseek(fp, 2, SEEK_SET)); EXPECT_EQ(2, ftell(fp)); ASSERT_NE(EOF, fputs("xxx", fp)); ASSERT_EQ(0, fflush(fp)); EXPECT_EQ(13, ftell(fp)); ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); EXPECT_EQ(13, ftell(fp)); ASSERT_EQ(0, fclose(fp)); AssertFileIs(tf.path, "0123456789xxx"); } TEST(STDIO_TEST, constants) { ASSERT_LE(FILENAME_MAX, PATH_MAX); ASSERT_EQ(L_tmpnam, PATH_MAX); } TEST(STDIO_TEST, perror) { ExecTestHelper eth; eth.Run([&]() { errno = EINVAL; perror("a b c"); exit(0); }, 0, "a b c: Invalid argument\n"); eth.Run([&]() { errno = EINVAL; perror(nullptr); exit(0); }, 0, "Invalid argument\n"); eth.Run([&]() { errno = EINVAL; perror(""); exit(0); }, 0, "Invalid argument\n"); } TEST(STDIO_TEST, puts) { ExecTestHelper eth; eth.Run([&]() { exit(puts("a b c")); }, 0, "a b c\n"); } TEST(STDIO_TEST, unlocked) { TemporaryFile tf; FILE* fp = fopen(tf.path, "w+"); ASSERT_TRUE(fp != nullptr); clearerr_unlocked(fp); ASSERT_FALSE(feof_unlocked(fp)); ASSERT_FALSE(ferror_unlocked(fp)); ASSERT_EQ(fileno(fp), fileno_unlocked(fp)); ASSERT_NE(EOF, putc_unlocked('a', fp)); ASSERT_NE(EOF, putc('b', fp)); ASSERT_NE(EOF, fputc_unlocked('c', fp)); ASSERT_NE(EOF, fputc('d', fp)); rewind(fp); ASSERT_EQ('a', getc_unlocked(fp)); ASSERT_EQ('b', getc(fp)); ASSERT_EQ('c', fgetc_unlocked(fp)); ASSERT_EQ('d', fgetc(fp)); rewind(fp); ASSERT_EQ(2U, fwrite_unlocked("AB", 1, 2, fp)); ASSERT_EQ(2U, fwrite("CD", 1, 2, fp)); ASSERT_EQ(0, fflush_unlocked(fp)); rewind(fp); char buf[BUFSIZ] = {}; ASSERT_EQ(2U, fread_unlocked(&buf[0], 1, 2, fp)); ASSERT_EQ(2U, fread(&buf[2], 1, 2, fp)); ASSERT_STREQ("ABCD", buf); rewind(fp); ASSERT_NE(EOF, fputs("hello ", fp)); ASSERT_NE(EOF, fputs_unlocked("world", fp)); ASSERT_NE(EOF, fputc('\n', fp)); rewind(fp); ASSERT_TRUE(fgets_unlocked(buf, sizeof(buf), fp) != nullptr); ASSERT_STREQ("hello world\n", buf); ASSERT_EQ(0, fclose(fp)); } TEST(STDIO_TEST, fseek_64bit) { TemporaryFile tf; FILE* fp = fopen64(tf.path, "w+"); ASSERT_TRUE(fp != nullptr); ASSERT_EQ(0, fseeko64(fp, 0x2'0000'0000, SEEK_SET)); ASSERT_EQ(0x2'0000'0000, ftello64(fp)); ASSERT_EQ(0, fseeko64(fp, 0x1'0000'0000, SEEK_CUR)); ASSERT_EQ(0x3'0000'0000, ftello64(fp)); ASSERT_EQ(0, fclose(fp)); } // POSIX requires that fseek/fseeko fail with EOVERFLOW if the new file offset // isn't representable in long/off_t. TEST(STDIO_TEST, fseek_overflow_32bit) { TemporaryFile tf; FILE* fp = fopen64(tf.path, "w+"); ASSERT_EQ(0, ftruncate64(fileno(fp), 0x2'0000'0000)); // Bionic implements overflow checking for SEEK_CUR, but glibc doesn't. #if defined(__BIONIC__) && !defined(__LP64__) ASSERT_EQ(0, fseek(fp, 0x7fff'ffff, SEEK_SET)); ASSERT_EQ(-1, fseek(fp, 1, SEEK_CUR)); ASSERT_EQ(EOVERFLOW, errno); #endif // Neither Bionic nor glibc implement the overflow checking for SEEK_END. // (Aside: FreeBSD's libc is an example of a libc that checks both SEEK_CUR // and SEEK_END -- many C libraries check neither.) ASSERT_EQ(0, fseek(fp, 0, SEEK_END)); ASSERT_EQ(0x2'0000'0000, ftello64(fp)); fclose(fp); } TEST(STDIO_TEST, dev_std_files) { // POSIX only mentions /dev/stdout, but we should have all three (http://b/31824379). char path[PATH_MAX]; ssize_t length = readlink("/dev/stdin", path, sizeof(path)); ASSERT_LT(0, length); ASSERT_EQ("/proc/self/fd/0", std::string(path, length)); length = readlink("/dev/stdout", path, sizeof(path)); ASSERT_LT(0, length); ASSERT_EQ("/proc/self/fd/1", std::string(path, length)); length = readlink("/dev/stderr", path, sizeof(path)); ASSERT_LT(0, length); ASSERT_EQ("/proc/self/fd/2", std::string(path, length)); } TEST(STDIO_TEST, fread_with_locked_file) { // Reading an unbuffered/line-buffered file from one thread shouldn't block on // files locked on other threads, even if it flushes some line-buffered files. FILE* fp1 = fopen("/dev/zero", "r"); ASSERT_TRUE(fp1 != nullptr); flockfile(fp1); std::thread([] { for (int mode : { _IONBF, _IOLBF }) { FILE* fp2 = fopen("/dev/zero", "r"); ASSERT_TRUE(fp2 != nullptr); setvbuf(fp2, nullptr, mode, 0); ASSERT_EQ('\0', fgetc(fp2)); fclose(fp2); } }).join(); funlockfile(fp1); fclose(fp1); }